/*
 * disasm.c
 *
 * PowerPC 603e disassembler.
 *
 * When possible, invalid forms of instructions are checked for. To the best
 * of my knowledge, all appropriate load/store instructions are checked. I'm
 * not sure whether any other kinds of instructions need checking.
 */

/* Originally written by Bart Trzynadlowski for Supermodel project
 *
 * PowerPC 403 opcodes and MAME conversion by Ville Linde
 */

#include "cpuintrf.h"
#include "debugger.h"
#include "ppccom.h"

/*
 * Operand Formats
 *
 * These convey information on what operand fields are present and how they
 * ought to be printed.
 *
 * I'm fairly certain all of these are used, but that is not guaranteed.
 */

enum
{
    F_NONE,         // <no operands>
    F_LI,           // LI*4+PC if AA=0 else LI*4
    F_BCx,          // BO, BI, target_addr  used only by BCx
    F_RT_RA_0_SIMM, // rT, rA|0, SIMM       rA|0 means if rA == 0, print 0
    F_ADDIS,        // rT, rA, SIMM (printed as unsigned)   only used by ADDIS
    F_RT_RA_SIMM,   // rT, rA, SIMM
    F_RA_RT_UIMM,   // rA, rT, UIMM
    F_CMP_SIMM,     // crfD, L, A, SIMM
    F_CMP_UIMM,     // crfD, L, A, UIMM
    F_RT_RA_0_RB,   // rT, rA|0, rB
    F_RT_RA_RB,     // rT, rA, rB
    F_RT_D_RA_0,    // rT, d(rA|0)
    F_RT_D_RA,      // rT, d(rA)
    F_RA_RT_RB,     // rA, rT, rB
    F_FRT_D_RA_0,   // frT, d(RA|0)
    F_FRT_D_RA,     // frT, d(RA)
    F_FRT_RA_0_RB,  // frT, rA|0, rB
    F_FRT_RA_RB,    // frT, rA, rB
    F_TWI,          // TO, rA, SIMM         only used by TWI instruction
    F_CMP,          // crfD, L, rA, rB
    F_RA_RT,        // rA, rT
    F_RA_0_RB,      // rA|0, rB
    F_FRT_FRB,      // frT, frB
    F_FCMP,         // crfD, frA, frB
    F_CRFD_CRFS,    // crfD, crfS
    F_MCRXR,        // crfD                 only used by MCRXR
    F_RT,           // rT
    F_MFSR,         // rT, SR               only used by MFSR
    F_MTSR,         // SR, rT               only used by MTSR
    F_MFFSx,        // frT                  only used by MFFSx
    F_FCRBD,        // crbD                 FPSCR[crbD]
    F_MTFSFIx,      // crfD, IMM            only used by MTFSFIx
    F_RB,           // rB
    F_TW,           // TO, rA, rB           only used by TW
    F_RT_RA_0_NB,   // rT, rA|0, NB         print 32 if NB == 0
    F_SRAWIx,       // rA, rT, SH           only used by SRAWIx
    F_BO_BI,        // BO, BI
    F_CRBD_CRBA_CRBB,   // crbD, crbA, crbB
    F_RT_SPR,       // rT, SPR              and TBR
    F_MTSPR,        // SPR, rT              only used by MTSPR
    F_MTCRF,        // CRM, rT              only used by MTCRF
    F_MTFSFx,       // FM, frB              only used by MTFSFx
	F_RT_DCR,		// rT, DCR
	F_MTDCR,		// DCR, rT
    F_RT_RA,        // rT, rA
    F_FRT_FRA_FRC_FRB,  // frT, frA, frC, frB
    F_FRT_FRA_FRB,  // frT, frA, frB
    F_FRT_FRA_FRC,  // frT, frA, frC
    F_RA_RT_SH_MB_ME,   // rA, rT, SH, MB, ME
    F_RLWNMx,       // rT, rA, rB, MB, ME   only used by RLWNMx
    F_RT_RB,        // rT, rB
};

/*
 * Flags
 */

#define FL_OE           (1 << 0)    // if there is an OE field
#define FL_RC           (1 << 1)    // if there is an RC field
#define FL_LK           (1 << 2)    // if there is an LK field
#define FL_AA           (1 << 3)    // if there is an AA field
#define FL_CHECK_RA_RT  (1 << 4)    // assert rA!=0 and rA!=rT
#define FL_CHECK_RA     (1 << 5)    // assert rA!=0
#define FL_CHECK_LSWI   (1 << 6)    // specific check for LSWI validity
#define FL_CHECK_LSWX   (1 << 7)    // specific check for LSWX validity
#define FL_SO			(1 << 8)	// use DASMFLAG_STEP_OUT


/*
 * Instruction Descriptor
 *
 * Describes the layout of an instruction.
 */

typedef struct
{
	char	mnem[32];	// mnemonic
	UINT32	match;		// bit pattern of instruction after it has been masked
	UINT32	mask;		// mask of variable fields (AND with ~mask to compare w/
						// bit pattern to determine a match)
	int	format;			// operand format
	int	flags;			// flags
} IDESCR;

/*
 * Instruction Table
 *
 * Table of instruction descriptors which allows the disassembler to decode
 * and print instructions.
 */

static const IDESCR itab[] =
{
    { "add",    D_OP(31)|D_XO(266), M_RT|M_RA|M_RB|M_OE|M_RC,   F_RT_RA_RB,     FL_OE|FL_RC },
    { "addc",   D_OP(31)|D_XO(10),  M_RT|M_RA|M_RB|M_OE|M_RC,   F_RT_RA_RB,     FL_OE|FL_RC },
    { "adde",   D_OP(31)|D_XO(138), M_RT|M_RA|M_RB|M_OE|M_RC,   F_RT_RA_RB,     FL_OE|FL_RC },
    { "addi",   D_OP(14),           M_RT|M_RA|M_SIMM,           F_RT_RA_0_SIMM, 0           },
    { "addic",  D_OP(12),           M_RT|M_RA|M_SIMM,           F_RT_RA_SIMM,   0           },
    { "addic.", D_OP(13),           M_RT|M_RA|M_SIMM,           F_RT_RA_SIMM,   0           },
    { "addis",  D_OP(15),           M_RT|M_RA|M_SIMM,           F_ADDIS,        0           },
    { "addme",  D_OP(31)|D_XO(234), M_RT|M_RA|M_OE|M_RC,        F_RT_RA,        FL_OE|FL_RC },
    { "addze",  D_OP(31)|D_XO(202), M_RT|M_RA|M_OE|M_RC,        F_RT_RA,        FL_OE|FL_RC },
    { "and",    D_OP(31)|D_XO(28),  M_RT|M_RA|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
    { "andc",   D_OP(31)|D_XO(60),  M_RT|M_RA|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
    { "andi.",  D_OP(28),           M_RT|M_RA|M_UIMM,           F_RA_RT_UIMM,   0           },
    { "andis.", D_OP(29),           M_RT|M_RA|M_UIMM,           F_RA_RT_UIMM,   0           },
    { "b",      D_OP(18),           M_LI|M_AA|M_LK,             F_LI,           FL_AA|FL_LK },
    { "bc",     D_OP(16),           M_BO|M_BI|M_BD|M_AA|M_LK,   F_BCx,          FL_AA|FL_LK },
    { "bcctr",  D_OP(19)|D_XO(528), M_BO|M_BI|M_LK,             F_BO_BI,        FL_LK       },
    { "bclr",   D_OP(19)|D_XO(16),  M_BO|M_BI|M_LK,             F_BO_BI,        FL_LK|FL_SO },
    { "cmp",    D_OP(31)|D_XO(0),   M_CRFD|M_RA|M_RB,           F_CMP,          0           },
    { "cmpd",   D_OP(31)|D_XO(0)|M_L,M_CRFD|M_RA|M_RB,          F_CMP,          0           },
    { "cmpi",   D_OP(11),           M_CRFD|M_RA|M_SIMM,         F_CMP_SIMM,     0           },
    { "cmpdi",  D_OP(11)|M_L,       M_CRFD|M_RA|M_SIMM,         F_CMP_SIMM,     0           },
    { "cmpl",   D_OP(31)|D_XO(32),  M_CRFD|M_RA|M_RB,           F_CMP,          0           },
    { "cmpld",  D_OP(31)|D_XO(32)|M_L,M_CRFD|M_RA|M_RB,         F_CMP,          0           },
    { "cmpli",  D_OP(10),           M_CRFD|M_RA|M_UIMM,         F_CMP_UIMM,     0           },
    { "cmpldi", D_OP(10)|M_L,       M_CRFD|M_RA|M_UIMM,         F_CMP_UIMM,     0           },
    { "cntlzw", D_OP(31)|D_XO(26),  M_RT|M_RA|M_RC,             F_RA_RT,        FL_RC       },
    { "crand",  D_OP(19)|D_XO(257), M_CRBD|M_CRBA|M_CRBB,       F_CRBD_CRBA_CRBB,   0       },
    { "crandc", D_OP(19)|D_XO(129), M_CRBD|M_CRBA|M_CRBB,       F_CRBD_CRBA_CRBB,   0       },
    { "creqv",  D_OP(19)|D_XO(289), M_CRBD|M_CRBA|M_CRBB,       F_CRBD_CRBA_CRBB,   0       },
    { "crnand", D_OP(19)|D_XO(225), M_CRBD|M_CRBA|M_CRBB,       F_CRBD_CRBA_CRBB,   0       },
    { "crnor",  D_OP(19)|D_XO(33),  M_CRBD|M_CRBA|M_CRBB,       F_CRBD_CRBA_CRBB,   0       },
    { "cror",   D_OP(19)|D_XO(449), M_CRBD|M_CRBA|M_CRBB,       F_CRBD_CRBA_CRBB,   0       },
    { "crorc",  D_OP(19)|D_XO(417), M_CRBD|M_CRBA|M_CRBB,       F_CRBD_CRBA_CRBB,   0       },
    { "crxor",  D_OP(19)|D_XO(193), M_CRBD|M_CRBA|M_CRBB,       F_CRBD_CRBA_CRBB,   0       },
    { "dcba",   D_OP(31)|D_XO(758), M_RA|M_RB,                  F_RA_0_RB,      0           },
    { "dcbf",   D_OP(31)|D_XO(86),  M_RA|M_RB,                  F_RA_0_RB,      0           },
    { "dcbi",   D_OP(31)|D_XO(470), M_RA|M_RB,                  F_RA_0_RB,      0           },
    { "dcbst",  D_OP(31)|D_XO(54),  M_RA|M_RB,                  F_RA_0_RB,      0           },
    { "dcbt",   D_OP(31)|D_XO(278), M_RA|M_RB,                  F_RA_0_RB,      0           },
    { "dcbtst", D_OP(31)|D_XO(246), M_RA|M_RB,                  F_RA_0_RB,      0           },
    { "dcbz",   D_OP(31)|D_XO(1014),M_RA|M_RB,                  F_RA_0_RB,      0           },
	{ "dccci",	D_OP(31)|D_XO(454),	M_RA|M_RB,					F_RA_0_RB,		0			},
	{ "dcread",	D_OP(31)|D_XO(486), M_RA|M_RB,					F_RT_RA_RB,		0			},
    { "divw",   D_OP(31)|D_XO(491), M_RT|M_RA|M_RB|M_OE|M_RC,   F_RT_RA_RB,     FL_OE|FL_RC },
    { "divwu",  D_OP(31)|D_XO(459), M_RT|M_RA|M_RB|M_OE|M_RC,   F_RT_RA_RB,     FL_OE|FL_RC },
	{ "dsa",	D_OP(31)|D_XO(628),	0,							0,				0			},
    { "eciwx",  D_OP(31)|D_XO(310), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "ecowx",  D_OP(31)|D_XO(438), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "eieio",  D_OP(31)|D_XO(854), 0,                          F_NONE,         0           },
    { "eqv",    D_OP(31)|D_XO(284), M_RT|M_RA|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
	{ "esa",	D_OP(31)|D_XO(596),	0,							0,				0			},
    { "extsb",  D_OP(31)|D_XO(954), M_RT|M_RA|M_RC,             F_RA_RT,        FL_RC       },
    { "extsh",  D_OP(31)|D_XO(922), M_RT|M_RA|M_RC,             F_RA_RT,        FL_RC       },
    { "fabs",   D_OP(63)|D_XO(264), M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "fadd",   D_OP(63)|D_XO(21),  M_RT|M_RA|M_RB|M_RC,        F_FRT_FRA_FRB,  FL_RC       },
    { "fadds",  D_OP(59)|D_XO(21),  M_RT|M_RA|M_RB|M_RC,        F_FRT_FRA_FRB,  FL_RC       },
    { "fcmpo",  D_OP(63)|D_XO(32),  M_CRFD|M_RA|M_RB,           F_FCMP,         0           },
    { "fcmpu",  D_OP(63)|D_XO(0),   M_CRFD|M_RA|M_RB,           F_FCMP,         0           },
    { "fctiw",  D_OP(63)|D_XO(14),  M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "fctiwz", D_OP(63)|D_XO(15),  M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "fdiv",   D_OP(63)|D_XO(18),  M_RT|M_RA|M_RB|M_RC,        F_FRT_FRA_FRB,  FL_RC       },
    { "fdivs",  D_OP(59)|D_XO(18),  M_RT|M_RA|M_RB|M_RC,        F_FRT_FRA_FRB,  FL_RC       },
    { "fmadd",  D_OP(63)|D_XO(29),  M_RT|M_RA|M_RB|M_REGC|M_RC, F_FRT_FRA_FRC_FRB,  FL_RC   },
    { "fmadds", D_OP(59)|D_XO(29),  M_RT|M_RA|M_RB|M_REGC|M_RC, F_FRT_FRA_FRC_FRB,  FL_RC   },
    { "fmr",    D_OP(63)|D_XO(72),  M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "fmsub",  D_OP(63)|D_XO(28),  M_RT|M_RA|M_RB|M_REGC|M_RC, F_FRT_FRA_FRC_FRB,  FL_RC   },
    { "fmsubs", D_OP(59)|D_XO(28),  M_RT|M_RA|M_RB|M_REGC|M_RC, F_FRT_FRA_FRC_FRB,  FL_RC   },
    { "fmul",   D_OP(63)|D_XO(25),  M_RT|M_RA|M_REGC|M_RC,      F_FRT_FRA_FRC,  FL_RC       },
    { "fmuls",  D_OP(59)|D_XO(25),  M_RT|M_RA|M_REGC|M_RC,      F_FRT_FRA_FRC,  FL_RC       },
    { "fnabs",  D_OP(63)|D_XO(136), M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "fneg",   D_OP(63)|D_XO(40),  M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "fnmadd", D_OP(63)|D_XO(31),  M_RT|M_RA|M_RB|M_REGC|M_RC, F_FRT_FRA_FRC_FRB,  FL_RC   },
    { "fnmadds",D_OP(59)|D_XO(31),  M_RT|M_RA|M_RB|M_REGC|M_RC, F_FRT_FRA_FRC_FRB,  FL_RC   },
    { "fnmsub", D_OP(63)|D_XO(30),  M_RT|M_RA|M_RB|M_REGC|M_RC, F_FRT_FRA_FRC_FRB,  FL_RC   },
    { "fnmsubs",D_OP(59)|D_XO(30),  M_RT|M_RA|M_RB|M_REGC|M_RC, F_FRT_FRA_FRC_FRB,  FL_RC   },
    { "fres",   D_OP(59)|D_XO(24),  M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "frsp",   D_OP(63)|D_XO(12),  M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "frsqrte",D_OP(63)|D_XO(26),  M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "fsel",   D_OP(63)|D_XO(23),  M_RT|M_RA|M_RB|M_REGC|M_RC, F_FRT_FRA_FRC_FRB,  FL_RC   },
    { "fsqrt",  D_OP(63)|D_XO(22),  M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "fsqrts", D_OP(59)|D_XO(22),  M_RT|M_RB|M_RC,             F_FRT_FRB,      FL_RC       },
    { "fsub",   D_OP(63)|D_XO(20),  M_RT|M_RA|M_RB|M_RC,        F_FRT_FRA_FRB,  FL_RC       },
    { "fsubs",  D_OP(59)|D_XO(20),  M_RT|M_RA|M_RB|M_RC,        F_FRT_FRA_FRB,  FL_RC       },
    { "icbi",   D_OP(31)|D_XO(982), M_RA|M_RB,                  F_RA_0_RB,      0           },
	{ "icbt",	D_OP(31)|D_XO(262), M_RA|M_RB,					F_RA_0_RB,		0			},
	{ "iccci",	D_OP(31)|D_XO(966), M_RA|M_RB,					F_RA_0_RB,		0			},
	{ "icread",	D_OP(31)|D_XO(998), M_RA|M_RB,					F_RA_0_RB,		0			},
    { "isync",  D_OP(19)|D_XO(150), 0,                          F_NONE,         0           },
    { "lbz",    D_OP(34),           M_RT|M_RA|M_D,              F_RT_D_RA_0,    0           },
    { "lbzu",   D_OP(35),           M_RT|M_RA|M_D,              F_RT_D_RA,      FL_CHECK_RA_RT },
    { "lbzux",  D_OP(31)|D_XO(119), M_RT|M_RA|M_RB,             F_RT_RA_RB,     FL_CHECK_RA_RT },
    { "lbzx",   D_OP(31)|D_XO(87),  M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "lfd",    D_OP(50),           M_RT|M_RA|M_D,              F_FRT_D_RA_0,   0           },
    { "lfdu",   D_OP(51),           M_RT|M_RA|M_D,              F_FRT_D_RA,     FL_CHECK_RA },
    { "lfdux",  D_OP(31)|D_XO(631), M_RT|M_RA|M_RB,             F_FRT_RA_RB,    FL_CHECK_RA },
    { "lfdx",   D_OP(31)|D_XO(599), M_RT|M_RA|M_RB,             F_FRT_RA_0_RB,  0           },
    { "lfs",    D_OP(48),           M_RT|M_RA|M_D,              F_FRT_D_RA_0,   0           },
    { "lfsu",   D_OP(49),           M_RT|M_RA|M_D,              F_FRT_D_RA,     FL_CHECK_RA },
    { "lfsux",  D_OP(31)|D_XO(567), M_RT|M_RA|M_RB,             F_FRT_RA_RB,    FL_CHECK_RA },
    { "lfsx",   D_OP(31)|D_XO(535), M_RT|M_RA|M_RB,             F_FRT_RA_0_RB,  0           },
    { "lha",    D_OP(42),           M_RT|M_RA|M_D,              F_RT_D_RA_0,    0           },
    { "lhau",   D_OP(43),           M_RT|M_RA|M_D,              F_RT_D_RA,      FL_CHECK_RA_RT },
    { "lhaux",  D_OP(31)|D_XO(375), M_RT|M_RA|M_RB,             F_RT_RA_RB,     FL_CHECK_RA_RT },
    { "lhax",   D_OP(31)|D_XO(343), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "lhbrx",  D_OP(31)|D_XO(790), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "lhz",    D_OP(40),           M_RT|M_RA|M_D,              F_RT_D_RA_0,    0           },
    { "lhzu",   D_OP(41),           M_RT|M_RA|M_D,              F_RT_D_RA,      FL_CHECK_RA_RT },
    { "lhzux",  D_OP(31)|D_XO(311), M_RT|M_RA|M_RB,             F_RT_RA_RB,     FL_CHECK_RA_RT },
    { "lhzx",   D_OP(31)|D_XO(279), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "lmw",    D_OP(46),           M_RT|M_RA|M_D,              F_RT_D_RA_0,    0           },
    { "lswi",   D_OP(31)|D_XO(597), M_RT|M_RA|M_NB,             F_RT_RA_0_NB,   FL_CHECK_LSWI },
    { "lswx",   D_OP(31)|D_XO(533), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   FL_CHECK_LSWX },
    { "lwarx",  D_OP(31)|D_XO(20),  M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "lwbrx",  D_OP(31)|D_XO(534), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "lwz",    D_OP(32),           M_RT|M_RA|M_D,              F_RT_D_RA_0,    0           },
    { "lwzu",   D_OP(33),           M_RT|M_RA|M_D,              F_RT_D_RA,      FL_CHECK_RA_RT },
    { "lwzux",  D_OP(31)|D_XO(55),  M_RT|M_RA|M_RB,             F_RT_RA_RB,     FL_CHECK_RA_RT },
    { "lwzx",   D_OP(31)|D_XO(23),  M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "mcrf",   D_OP(19)|D_XO(0),   M_CRFD|M_CRFS,              F_CRFD_CRFS,    0           },
    { "mcrfs",  D_OP(63)|D_XO(64),  M_CRFD|M_CRFS,              F_CRFD_CRFS,    0           },
    { "mcrxr",  D_OP(31)|D_XO(512), M_CRFD,                     F_MCRXR,        0           },
    { "mfcr",   D_OP(31)|D_XO(19),  M_RT,                       F_RT,           0           },
	{ "mfdcr",	D_OP(31)|D_XO(323),	M_RT|M_DCR,					F_RT_DCR,		0			},
    { "mffs",   D_OP(63)|D_XO(583), M_RT|M_RC,                  F_MFFSx,        FL_RC       },
    { "mfmsr",  D_OP(31)|D_XO(83),  M_RT,                       F_RT,           0           },
    { "mfspr",  D_OP(31)|D_XO(339), M_RT|M_SPR,                 F_RT_SPR,       0           },
    { "mfsr",   D_OP(31)|D_XO(595), M_RT|M_SR,                  F_MFSR,         0           },
    { "mfsrin", D_OP(31)|D_XO(659), M_RT|M_RB,                  F_RT_RB,        0           },
    { "mftb",   D_OP(31)|D_XO(371), M_RT|M_TBR,                 F_RT_SPR,       0           },
    { "mtcrf",  D_OP(31)|D_XO(144), M_RT|M_CRM,                 F_MTCRF,        0           },
	{ "mtdcr",	D_OP(31)|D_XO(451),	M_RT|M_DCR,					F_MTDCR,		0			},
    { "mtfsb0", D_OP(63)|D_XO(70),  M_CRBD|M_RC,                F_FCRBD,        FL_RC       },
    { "mtfsb1", D_OP(63)|D_XO(38),  M_CRBD|M_RC,                F_FCRBD,        FL_RC       },
    { "mtfsf",  D_OP(63)|D_XO(711), M_FM|M_RB|M_RC,             F_MTFSFx,       FL_RC       },
    { "mtfsfi", D_OP(63)|D_XO(134), M_CRFD|M_IMM|M_RC,          F_MTFSFIx,      FL_RC       },
    { "mtmsr",  D_OP(31)|D_XO(146), M_RT,                       F_RT,           0           },
    { "mtspr",  D_OP(31)|D_XO(467), M_RT|M_SPR,                 F_MTSPR,        0           },
    { "mtsr",   D_OP(31)|D_XO(210), M_RT|M_SR,                  F_MTSR,         0           },
    { "mtsrin", D_OP(31)|D_XO(242), M_RT|M_RB,                  F_RT_RB,        0           },
    { "mulhw",  D_OP(31)|D_XO(75),  M_RT|M_RA|M_RB|M_RC,        F_RT_RA_RB,     FL_RC       },
    { "mulhwu", D_OP(31)|D_XO(11),  M_RT|M_RA|M_RB|M_RC,        F_RT_RA_RB,     FL_RC       },
    { "mulli",  D_OP(7),            M_RT|M_RA|M_SIMM,           F_RT_RA_SIMM,   0           },
    { "mullw",  D_OP(31)|D_XO(235), M_RT|M_RA|M_RB|M_OE|M_RC,   F_RT_RA_RB,     FL_OE|FL_RC },
    { "nand",   D_OP(31)|D_XO(476), M_RA|M_RT|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
    { "neg",    D_OP(31)|D_XO(104), M_RT|M_RA|M_OE|M_RC,        F_RT_RA,        FL_OE|FL_RC },
    { "nor",    D_OP(31)|D_XO(124), M_RT|M_RA|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
    { "or",     D_OP(31)|D_XO(444), M_RT|M_RA|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
    { "orc",    D_OP(31)|D_XO(412), M_RT|M_RA|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
    { "ori",    D_OP(24),           M_RT|M_RA|M_UIMM,           F_RA_RT_UIMM,   0           },
    { "oris",   D_OP(25),           M_RT|M_RA|M_UIMM,           F_RA_RT_UIMM,   0           },
    { "rfi",    D_OP(19)|D_XO(50),  0,                          F_NONE,         0           },
	{ "rfci",	D_OP(19)|D_XO(51),	0,							F_NONE,			0			},
    { "rlwimi", D_OP(20),           M_RT|M_RA|M_SH|M_MB|M_ME|M_RC,  F_RA_RT_SH_MB_ME,   FL_RC   },
    { "rlwinm", D_OP(21),           M_RT|M_RA|M_SH|M_MB|M_ME|M_RC,  F_RA_RT_SH_MB_ME,   FL_RC   },
    { "rlwnm",  D_OP(23),           M_RT|M_RA|M_RB|M_MB|M_ME|M_RC,  F_RLWNMx,   FL_RC       },
    { "sc",     D_OP(17)|2,         0,                          F_NONE,         0           },
    { "slw",    D_OP(31)|D_XO(24),  M_RT|M_RA|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
    { "sraw",   D_OP(31)|D_XO(792), M_RT|M_RA|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
    { "srawi",  D_OP(31)|D_XO(824), M_RT|M_RA|M_SH|M_RC,        F_SRAWIx,       FL_RC       },
    { "srw",    D_OP(31)|D_XO(536), M_RT|M_RA|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
    { "stb",    D_OP(38),           M_RT|M_RA|M_D,              F_RT_D_RA_0,    0           },
    { "stbu",   D_OP(39),           M_RT|M_RA|M_D,              F_RT_D_RA,      FL_CHECK_RA },
    { "stbux",  D_OP(31)|D_XO(247), M_RT|M_RA|M_RB,             F_RT_RA_RB,     FL_CHECK_RA },
    { "stbx",   D_OP(31)|D_XO(215), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "stfd",   D_OP(54),           M_RT|M_RA|M_D,              F_FRT_D_RA_0,   0           },
    { "stfdu",  D_OP(55),           M_RT|M_RA|M_D,              F_FRT_D_RA,     FL_CHECK_RA },
    { "stfdux", D_OP(31)|D_XO(759), M_RT|M_RA|M_RB,             F_FRT_RA_RB,    FL_CHECK_RA },
    { "stfdx",  D_OP(31)|D_XO(727), M_RT|M_RA|M_RB,             F_FRT_RA_0_RB,  0           },
    { "stfiwx", D_OP(31)|D_XO(983), M_RT|M_RA|M_RB,             F_FRT_RA_0_RB,  0           },
    { "stfs",   D_OP(52),           M_RT|M_RA|M_D,              F_FRT_D_RA_0,   0           },
    { "stfsu",  D_OP(53),           M_RT|M_RA|M_D,              F_FRT_D_RA,     FL_CHECK_RA },
    { "stfsux", D_OP(31)|D_XO(695), M_RT|M_RA|M_RB,             F_FRT_RA_RB,    FL_CHECK_RA },
    { "stfsx",  D_OP(31)|D_XO(663), M_RT|M_RA|M_RB,             F_FRT_RA_0_RB,  0           },
    { "sth",    D_OP(44),           M_RT|M_RA|M_D,              F_RT_D_RA_0,    0           },
    { "sthbrx", D_OP(31)|D_XO(918), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "sthu",   D_OP(45),           M_RT|M_RA|M_D,              F_RT_D_RA,      FL_CHECK_RA },
    { "sthux",  D_OP(31)|D_XO(439), M_RT|M_RA|M_RB,             F_RT_RA_RB,     FL_CHECK_RA },
    { "sthx",   D_OP(31)|D_XO(407), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "stmw",   D_OP(47),           M_RT|M_RA|M_D,              F_RT_D_RA_0,    0           },
    { "stswi",  D_OP(31)|D_XO(725), M_RT|M_RA|M_NB,             F_RT_RA_0_NB,   0           },
    { "stswx",  D_OP(31)|D_XO(661), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "stw",    D_OP(36),           M_RT|M_RA|M_D,              F_RT_D_RA_0,    0           },
    { "stwbrx", D_OP(31)|D_XO(662), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "stwcx.", D_OP(31)|D_XO(150)|1,   M_RT|M_RA|M_RB,         F_RT_RA_0_RB,   0           },
    { "stwu",   D_OP(37),           M_RT|M_RA|M_D,              F_RT_D_RA,      FL_CHECK_RA },
    { "stwux",  D_OP(31)|D_XO(183), M_RT|M_RA|M_RB,             F_RT_RA_RB,     FL_CHECK_RA },
    { "stwx",   D_OP(31)|D_XO(151), M_RT|M_RA|M_RB,             F_RT_RA_0_RB,   0           },
    { "subf",   D_OP(31)|D_XO(40),  M_RT|M_RA|M_RB|M_OE|M_RC,   F_RT_RA_RB,     FL_OE|FL_RC },
    { "subfc",  D_OP(31)|D_XO(8),   M_RT|M_RA|M_RB|M_OE|M_RC,   F_RT_RA_RB,     FL_OE|FL_RC },
    { "subfe",  D_OP(31)|D_XO(136), M_RT|M_RA|M_RB|M_OE|M_RC,   F_RT_RA_RB,     FL_OE|FL_RC },
    { "subfic", D_OP(8),            M_RT|M_RA|M_SIMM,           F_RT_RA_SIMM,   0           },
    { "subfme", D_OP(31)|D_XO(232), M_RT|M_RA|M_OE|M_RC,        F_RT_RA,        FL_OE|FL_RC },
    { "subfze", D_OP(31)|D_XO(200), M_RT|M_RA|M_OE|M_RC,        F_RT_RA,        FL_OE|FL_RC },
    { "sync",   D_OP(31)|D_XO(598), 0,                          F_NONE,         0           },
    { "tlbia",  D_OP(31)|D_XO(370), 0,                          F_NONE,         0           },
    { "tlbie",  D_OP(31)|D_XO(306), M_RB,                       F_RB,           0           },
    { "tlbsync",D_OP(31)|D_XO(566), 0,                          F_NONE,         0           },
    { "tw",     D_OP(31)|D_XO(4),   M_TO|M_RA|M_RB,             F_TW,           0           },
    { "twi",    D_OP(3),            M_TO|M_RA|M_SIMM,           F_TWI,          0           },
	{ "wrtee",	D_OP(31)|D_XO(131),	M_RT,						F_RT,			0			},
	{ "wrteei",	D_OP(31)|D_XO(163),	0,							0,				0			},
    { "xor",    D_OP(31)|D_XO(316), M_RT|M_RA|M_RB|M_RC,        F_RA_RT_RB,     FL_RC       },
    { "xori",   D_OP(26),           M_RT|M_RA|M_UIMM,           F_RA_RT_UIMM,   0           },
    { "xoris",  D_OP(27),           M_RT|M_RA|M_UIMM,           F_RA_RT_UIMM,   0           },

    /*
     * PowerPC 603e/EC603e-specific instructions
     */

    { "tlbld",  D_OP(31)|D_XO(978), M_RB,                       F_RB,           0           },
    { "tlbli",  D_OP(31)|D_XO(1010),M_RB,                       F_RB,           0           }
};

/*
 * CR Bits
 *
 * Use an index of BI&3 into this table to obtain the CR field bit name.
 */

static const char *const crbit[4] = { "lt", "gt", "eq", "so" };
static const char *const crnbit[4] = { "ge", "le", "ne", "nso" };


/*
 * SPR():
 *
 * Decode the SPR (or TBR) field and append the register name to dest. If
 * no name is associated with the field value, the value itself is printed.
 */

static void SPR(char *dest, int spr_field)
{
    int spr;

    /*
     * Construct the SPR number -- SPR field is 2 5-bit fields
     */

    spr = (spr_field >> 5) & 0x1f;
    spr |= (spr_field & 0x1f) << 5;

    /*
     * Append the SPR name to the destination string using strcat()
     */

	switch (spr)
	{
		/* UISA SPR register indexes */
		case SPR_XER:		strcat(dest, "xer");	break;
		case SPR_LR:		strcat(dest, "lr");		break;
		case SPR_CTR:		strcat(dest, "ctr");	break;

		/* VEA SPR register indexes */
		case SPRVEA_TBL_R:	strcat(dest, "tbl");	break;
		case SPRVEA_TBU_R:	strcat(dest, "tbu");	break;

		/* OEA SPR register indexes */
		case SPROEA_DSISR:	strcat(dest, "dsisr");	break;
		case SPROEA_DAR:	strcat(dest, "dar");	break;
		case SPROEA_DEC:	strcat(dest, "dec");	break;
		case SPROEA_SDR1:	strcat(dest, "sdr1");	break;
		case SPROEA_SRR0:	strcat(dest, "srr0");	break;
		case SPROEA_SRR1:	strcat(dest, "srr1");	break;
		case SPROEA_SPRG0:	strcat(dest, "sprg0");	break;
		case SPROEA_SPRG1:	strcat(dest, "sprg1");	break;
		case SPROEA_SPRG2:	strcat(dest, "sprg2");	break;
		case SPROEA_SPRG3:	strcat(dest, "sprg3");	break;
		case SPROEA_ASR:	strcat(dest, "asr");	break;
		case SPROEA_EAR:	strcat(dest, "ear");	break;
		case SPROEA_PVR:	strcat(dest, "pvr");	break;
		case SPROEA_IBAT0U:	strcat(dest, "ibat0u");	break;
		case SPROEA_IBAT0L:	strcat(dest, "ibat0l");	break;
		case SPROEA_IBAT1U:	strcat(dest, "ibat1u");	break;
		case SPROEA_IBAT1L:	strcat(dest, "ibat1l");	break;
		case SPROEA_IBAT2U:	strcat(dest, "ibat2u");	break;
		case SPROEA_IBAT2L:	strcat(dest, "ibat2l");	break;
		case SPROEA_IBAT3U:	strcat(dest, "ibat3u");	break;
		case SPROEA_IBAT3L:	strcat(dest, "ibat3l");	break;
		case SPROEA_DBAT0U:	strcat(dest, "dbat0u");	break;
		case SPROEA_DBAT0L:	strcat(dest, "dbat0l");	break;
		case SPROEA_DBAT1U:	strcat(dest, "dbat1u");	break;
		case SPROEA_DBAT1L:	strcat(dest, "dbat1l");	break;
		case SPROEA_DBAT2U:	strcat(dest, "dbat2u");	break;
		case SPROEA_DBAT2L:	strcat(dest, "dbat2l");	break;
		case SPROEA_DBAT3U:	strcat(dest, "dbat3u");	break;
		case SPROEA_DBAT3L:	strcat(dest, "dbat3l");	break;
		case SPROEA_DABR:	strcat(dest, "dabr/iac2");	break;  // unsupported on 603e/EC603e

		/* PowerPC 603E SPR register indexes */
		case SPR603_HID0:	strcat(dest, "hid0/dbsr");	break;
		case SPR603_HID1:	strcat(dest, "hid1");	break;
		case SPR603_DMISS:	strcat(dest, "dmiss");	break;
		case SPR603_DCMP:	strcat(dest, "dcmp");	break;
		case SPR603_HASH1:	strcat(dest, "hash1");	break;
		case SPR603_HASH2:	strcat(dest, "hash2/icdbdr");	break;
		case SPR603_IMISS:	strcat(dest, "imiss");	break;
		case SPR603_ICMP:	strcat(dest, "icmp/dear");	break;
		case SPR603_RPA:	strcat(dest, "rpa/evpr");	break;
		case SPR603_IABR:	strcat(dest, "iabr/dbcr");	break;

		/* PowerPC 4XX SPR register indexes */
		case SPR4XX_SGR:	strcat(dest, "sgr");	break;
		case SPR4XX_DCWR:	strcat(dest, "dcwr");	break;
		case SPR4XX_PID:	strcat(dest, "pid");	break;
		case SPR4XX_TBHU:	strcat(dest, "tbhu");	break;
		case SPR4XX_TBLU:	strcat(dest, "tblu");	break;
//      case SPR4XX_ICDBDR: strcat(dest, "icdbdr"); break;  // same as SPR603E_HASH2
//      case SPR4XX_DEAR:   strcat(dest, "dear");   break;  // same as SPR603E_ICMP
//      case SPR4XX_EVPR:   strcat(dest, "evpr");   break;  // same as SPR603E_RPA
		case SPR4XX_CDBCR:	strcat(dest, "cdbcr");	break;
		case SPR4XX_TSR:	strcat(dest, "tsr");	break;
		case SPR4XX_TCR:	strcat(dest, "tcr");	break;
		case SPR4XX_PIT:	strcat(dest, "pit");	break;
		case SPR4XX_TBHI:	strcat(dest, "tbhi");	break;
		case SPR4XX_TBLO:	strcat(dest, "tblo");	break;
		case SPR4XX_SRR2:	strcat(dest, "srr2");	break;
		case SPR4XX_SRR3:	strcat(dest, "srr3");	break;
//      case SPR4XX_DBSR:   strcat(dest, "dbsr");   break;  // same as SPR603E_HID0
//      case SPR4XX_DBCR:   strcat(dest, "dbcr");   break;  // same as SPR603E_IABR
		case SPR4XX_IAC1:	strcat(dest, "iac1");	break;
//      case SPR4XX_IAC2:   strcat(dest, "iac2");   break;  // same as SPROEA_DABR
		case SPR4XX_DAC1:	strcat(dest, "dac1");	break;
		case SPR4XX_DAC2:	strcat(dest, "dac2");	break;
		case SPR4XX_DCCR:	strcat(dest, "dccr");	break;
		case SPR4XX_ICCR:	strcat(dest, "iccr");	break;
		case SPR4XX_PBL1:	strcat(dest, "pbl1");	break;
		case SPR4XX_PBU1:	strcat(dest, "pbu1");	break;
		case SPR4XX_PBL2:	strcat(dest, "pbl2");	break;
		case SPR4XX_PBU2:	strcat(dest, "pbu2");	break;

		default:	sprintf(dest, "%s%d", dest, spr); break;
	}
}

static void DCR(char *dest, int dcr_field)
{
    int dcr;

    /*
     * Construct the DCR number -- DCR field is 2 5-bit fields
     */

    dcr = (dcr_field >> 5) & 0x1f;
    dcr |= (dcr_field & 0x1f) << 5;

    /*
     * Append the DCR name to the destination string using strcat()
     */

	switch (dcr)
	{
		case 144:	strcat(dest, "bear"); break;
		case 145:	strcat(dest, "besr"); break;
		case 128:	strcat(dest, "br0"); break;
		case 129:	strcat(dest, "br1"); break;
		case 130:	strcat(dest, "br2"); break;
		case 131:	strcat(dest, "br3"); break;
		case 132:	strcat(dest, "br4"); break;
		case 133:	strcat(dest, "br5"); break;
		case 134:	strcat(dest, "br6"); break;
		case 135:	strcat(dest, "br7"); break;
		case 112:	strcat(dest, "brh0"); break;
		case 113:	strcat(dest, "brh1"); break;
		case 114:	strcat(dest, "brh2"); break;
		case 115:	strcat(dest, "brh3"); break;
		case 116:	strcat(dest, "brh4"); break;
		case 117:	strcat(dest, "brh5"); break;
		case 118:	strcat(dest, "brh6"); break;
		case 119:	strcat(dest, "brh7"); break;
		case 196:	strcat(dest, "dmacc0"); break;
		case 204:	strcat(dest, "dmacc1"); break;
		case 212:	strcat(dest, "dmacc2"); break;
		case 220:	strcat(dest, "dmacc3"); break;
		case 192:	strcat(dest, "dmacr0"); break;
		case 200:	strcat(dest, "dmacr1"); break;
		case 208:	strcat(dest, "dmacr2"); break;
		case 216:	strcat(dest, "dmacr3"); break;
		case 193:	strcat(dest, "dmact0"); break;
		case 201:	strcat(dest, "dmact1"); break;
		case 209:	strcat(dest, "dmact2"); break;
		case 217:	strcat(dest, "dmact3"); break;
		case 194:	strcat(dest, "dmada0"); break;
		case 202:	strcat(dest, "dmada1"); break;
		case 210:	strcat(dest, "dmada2"); break;
		case 218:	strcat(dest, "dmada3"); break;
		case 195:	strcat(dest, "dmasa0"); break;
		case 203:	strcat(dest, "dmasa1"); break;
		case 211:	strcat(dest, "dmasa2"); break;
		case 219:	strcat(dest, "dmasa3"); break;
		case 224:	strcat(dest, "dmasr"); break;
		case 66:	strcat(dest, "exier"); break;
		case 64:	strcat(dest, "exisr"); break;
		case 160:	strcat(dest, "iocr"); break;

		default:    sprintf(dest, "%s%d", dest, dcr); break;
	}
}


/*
 * DecodeSigned16():
 *
 * Predecodes the SIMM field for us. If do_unsigned, it is printed as an
 * unsigned 16-bit integer.
 */

static void DecodeSigned16(char *outbuf, UINT32 op, int do_unsigned)
{
	INT16 s;

	s = G_SIMM(op);
	if (do_unsigned)    // sign extend to unsigned 32-bits
		sprintf(outbuf, "0x%04X", (UINT32) s);
	else                // print as signed 16 bits
	{
		if (s < 0)
		{
			s *= -1;
			sprintf(outbuf, "-0x%04X", s);
		}
		else
			sprintf(outbuf, "0x%04X",s);
	}
}

/*
 * Mask():
 *
 * Generate a mask from bit MB through ME (PPC-style backwards bit numbering.)
 */

static UINT32 Mask(int mb, int me)
{
	UINT32	i, mask;

	mb &= 31;
	me &= 31;

	i = mb;
	mask = 0;
	while (1)
	{
		mask |= (1 << (31 - i));
		if (i == me)
			break;
		i = (i + 1) & 31;
	}

	return mask;
}

/*
 * Check():
 *
 * Perform checks on the instruction as required by the flags. Returns 1 if
 * the instruction failed.
 */

#if 0
static int Check(UINT32 op, int flags)
{
	int nb, rt, ra;

	if( !flags ) return 0;	// nothing to check for!

	rt = G_RT(op);
	ra = G_RA(op);

	if (flags & FL_CHECK_RA_RT) // invalid if rA==0 or rA==rT
	{
		if ((G_RA(op) == 0) || (G_RA(op) == G_RT(op)))
			return 1;
	}

	if (flags & FL_CHECK_RA)    // invalid if rA==0
	{
		if (G_RA(op) == 0)
			return 1;
	}

	if (flags & FL_CHECK_LSWI)
	{
		/*
         * Check that rA is not in the range of registers to be loaded (even
         * if rA == 0)
         */

		nb = G_NB(op);

		if (ra >= rt && ra <= (rt + nb - 1))    return 1;
		if ((rt + nb - 1) > 31) // register wrap-around!
		{
			if (ra < ((rt + nb - 1) - 31))
				return 1;
		}
	}

	if (flags & FL_CHECK_LSWX)
	{
		/*
         * Check that rT != rA, rT != rB, and rD and rA both do not specify
         * R0.
         *
         * We cannot check fully whether rA or rB are in the range of
         * registers specified to be loaded because that depends on XER.
         */

		if (rt == ra || rt == G_RB(op) || ((rt == 0) && (ra == 0)))
			return 1;
	}

	return 0;   // passed checks
}
#endif
/*
 * Simplified():
 *
 * Handles all simplified instruction forms. Returns 1 if one was decoded,
 * otherwise 0 to indicate disassembly should carry on as normal.
 */

static int Simplified(UINT32 op, UINT32 vpc, char *signed16, char *mnem, char *oprs)
{
	UINT32  value, disp;

	value = G_SIMM(op); // value is fully sign-extended SIMM field
	if (value & 0x8000)
		value |= 0xffff0000;

	if (op == (D_OP(24)|D_RT(0)|D_RA(0)|D_UIMM(0)))
		strcat(mnem, "nop");        // ori r0,r0,0 -> nop
	else if ((op & ~(M_RT|M_RA|M_RB|M_RC)) == (D_OP(31)|D_XO(444)))
	{
		if (G_RT(op) == G_RB(op))
		{
			strcat(mnem, "mr");     // orx rA,rT,rT -> mrx rA,rT
			if (op & M_RC)  strcat(mnem, ".");
			sprintf(oprs, "r%d,r%d", G_RA(op), G_RT(op));
		}
		else
			return 0;
	}
	else if ((op & ~(M_RT|M_RA|M_RB|M_RC)) == (D_OP(31)|D_XO(124)))
	{
		if (G_RT(op) == G_RB(op))
		{
			strcat(mnem, "not");    // nor rA,rT,rT -> not rA,rT
			if (op & M_RC)  strcat(mnem, ".");
			sprintf(oprs, "r%d,r%d", G_RA(op), G_RT(op));
		}
		else
			return 0;
	}
	else if ((op & ~(M_RT|M_RA|M_SIMM)) == D_OP(14))
	{
		if (G_RA(op) == 0)
		{
			strcat(mnem, "li");     // addi rT,0,value -> li rT,value
			sprintf(oprs, "r%d,0x%08X", G_RT(op), value);
		}
		else
			return 0;
	}
	else if ((op & ~(M_RT|M_RA|M_SIMM)) == D_OP(15))
	{
		if (G_RA(op) == 0)
		{
			strcat(mnem, "li"); // addis rT,0,value -> li rT,(value<<16)
			sprintf(oprs, "r%d,0x%08X", G_RT(op), value << 16);
		}
		else
		{
			strcat(mnem, "addi");   // addis rT,rA,SIMM -> addi rT,rA,SIMM<<16
			sprintf(oprs, "r%d,r%d,0x%08X", G_RT(op), G_RA(op), value << 16);
		}
	}
	else if ((op & ~(M_RT|M_RA|M_UIMM)) == D_OP(29))
	{
		strcat(mnem, "andi.");  // andis. rA,rT,UIMM -> andi. rA,rT,UIMM<<16
		sprintf(oprs, "r%d,r%d,0x%08X", G_RA(op), G_RT(op), G_UIMM(op) << 16);
	}
	else if ((op & ~(M_RT|M_RA|M_UIMM)) == D_OP(25))
	{
		strcat(mnem, "ori");    // oris rA,rT,UIMM -> ori rA,rT,UIMM<<16
		sprintf(oprs, "r%d,r%d,0x%08X", G_RA(op), G_RT(op), G_UIMM(op) << 16);
	}
	else if ((op & ~(M_RT|M_RA|M_UIMM)) == D_OP(27))
	{
		strcat(mnem, "xori");   // xoris rA,rT,UIMM -> xori rA,rT,UIMM<<16
		sprintf(oprs, "r%d,r%d,0x%08X", G_RA(op), G_RT(op), G_UIMM(op) << 16);
	}
	else if ((op & ~(M_RT|M_RA|M_SH|M_MB|M_ME|M_RC)) == D_OP(20))
	{
		value = Mask(G_MB(op), G_ME(op));
		strcat(mnem, "rlwimi"); // rlwimi[.] rA,rT,SH,MB,ME -> rlwimi[.] rA,rT,SH,MASK
		if (op & M_RC) strcat(mnem, ".");
		sprintf(oprs, "r%d,r%d,%d,0x%08X", G_RA(op), G_RT(op), G_SH(op), value);
	}
	else if ((op & ~(M_RT|M_RA|M_SH|M_MB|M_ME|M_RC)) == D_OP(21))
	{
		value = Mask(G_MB(op), G_ME(op));
		if (G_SH(op) == 0)      // rlwinm[.] rA,rT,0,MB,ME -> and[.] rA,rT,MASK
		{
			strcat(mnem, "and");
			if (op & M_RC) strcat(mnem, ".");
			sprintf(oprs, "r%d,r%d,0x%08X", G_RA(op), G_RT(op), value);
		}
		else                    // rlwinm[.] rA,rT,SH,MASK
		{
			strcat(mnem, "rlwinm");
			if (op & M_RC) strcat(mnem, ".");
			sprintf(oprs, "r%d,r%d,%d,0x%08X", G_RA(op), G_RT(op), G_SH(op), value);
		}
	}
	else if ((op & ~(M_RT|M_RA|M_RB|M_MB|M_ME|M_RC)) == D_OP(23))
	{
		value = Mask(G_MB(op), G_ME(op));
		strcat(mnem, "rlwnm");  // rlwnm[.] rA,rT,SH,MB,ME -> rlwnm[.] rA,rT,SH,MASK
		if (op & M_RC) strcat(mnem, ".");
		sprintf(oprs, "r%d,r%d,r%d,0x%08X", G_RA(op), G_RT(op), G_RB(op), value);
	}
	else if ((op & ~(M_BO|M_BI|M_BD|M_AA|M_LK)) == D_OP(16))
	{
		disp = G_BD(op) * 4;
		if (disp & 0x00008000)
			disp |= 0xffff0000;

		switch (G_BO(op))
		{
			case 0x04:	case 0x05:	case 0x06:	case 0x07:
				strcat(mnem, "b");
				strcat(mnem, crnbit[G_BI(op) & 3]);
				break;
			case 0x0c:	case 0x0d:	case 0x0e:	case 0x0f:
				strcat(mnem, "b");
				strcat(mnem, crbit[G_BI(op) & 3]);
				break;
			case 0x10:	case 0x11:	case 0x18:	case 0x19:
				strcat(mnem, "bdnz");
				break;
			case 0x12:	case 0x13:	case 0x1a:	case 0x1b:
				strcat(mnem, "bdz");
				break;
			case 0x14:	case 0x15:	case 0x16:	case 0x17:
			case 0x1c:	case 0x1d:	case 0x1e:	case 0x1f:
				strcat(mnem, "b");
				break;
			default:
				return 0;
		}

		if (op & M_LK)  strcat(mnem, "l");
		if (op & M_AA)  strcat(mnem, "a");

		if (!(G_BO(op) & 0x10) && G_BI(op) / 4 != 0)
			sprintf(oprs, "cr%d,0x%08X", G_BI(op) / 4, disp + ((op & M_AA) ? 0 : vpc));
		else
			sprintf(oprs, "0x%08X", disp + ((op & M_AA) ? 0 : vpc));
	}
	else if ((op & ~(M_BO|M_BI|M_LK)) == (D_OP(19)|D_XO(528)) || (op & ~(M_BO|M_BI|M_LK)) == (D_OP(19)|D_XO(16)))
	{
		switch (G_BO(op))
		{
			case 0x04:	case 0x05:	case 0x06:	case 0x07:
				strcat(mnem, "b");
				strcat(mnem, crnbit[G_BI(op) & 3]);
				break;
			case 0x0c:	case 0x0d:	case 0x0e:	case 0x0f:
				strcat(mnem, "b");
				strcat(mnem, crbit[G_BI(op) & 3]);
				break;
			case 0x10:	case 0x11:	case 0x18:	case 0x19:
				strcat(mnem, "bdnz");
				break;
			case 0x12:	case 0x13:	case 0x1a:	case 0x1b:
				strcat(mnem, "bdz");
				break;
			case 0x14:	case 0x15:	case 0x16:	case 0x17:
			case 0x1c:	case 0x1d:	case 0x1e:	case 0x1f:
				strcat(mnem, "b");
				break;
			default:
				return 0;
		}

		strcat(mnem, (G_XO(op) == 528) ? "ctr" : "lr");
		if (op & M_LK)  strcat(mnem, "l");
		if (op & M_AA)  strcat(mnem, "a");

		if (!(G_BO(op) & 0x10) && G_BI(op) / 4 != 0)
			sprintf(oprs, "cr%d", G_BI(op) / 4);
	}
	else if ((op & ~(M_RT|M_RA|M_RB|M_OE|M_RC)) == (D_OP(31)|D_XO(40)))
	{
		strcat(mnem, "sub");
		if (op & M_OE) strcat(mnem, "o");
		if (op & M_RC) strcat(mnem, ".");
		sprintf(oprs, "r%d,r%d,r%d", G_RT(op), G_RB(op), G_RA(op));
	}
	else if ((op & ~(M_RT|M_RA|M_RB|M_OE|M_RC)) == (D_OP(31)|D_XO(8)))
	{
		strcat(mnem, "subc");
		if (op & M_OE) strcat(mnem, "o");
		if (op & M_RC) strcat(mnem, ".");
		sprintf(oprs, "r%d,r%d,r%d", G_RT(op), G_RB(op), G_RA(op));
	}
	else
		return 0;   // no match

	return 1;
}

offs_t ppc_dasm_one(char *buffer, UINT32 pc, UINT32 op)
{
	char signed16[12];
	UINT32 disp;
	int i,j;
	char mnem[200];
	char oprs[200];
	offs_t flags = DASMFLAG_SUPPORTED;

	mnem[0] = '\0'; // so we can use strcat()
	oprs[0] = '\0';

	/*
     * Decode signed 16-bit fields (SIMM and d) to spare us the work later
     */

	DecodeSigned16(signed16, op, 0);

	/*
     * Try simplified forms first, then real instructions
     */

	if( Simplified(op, pc, signed16, mnem, oprs) ) {
		buffer += sprintf(buffer, "%s", mnem);
		for( j = strlen(mnem); j < 10; j++ ) {
			buffer += sprintf(buffer, " ");
		}
		buffer += sprintf(buffer, "%s", oprs);
		return 4 | flags;
	}

	/*
     * Search for the instruction in the list and print it if there's a match
     */

	for (i = 0; i < sizeof(itab) / sizeof(IDESCR); i++)
	{
		if ((op & ~itab[i].mask) == itab[i].match)  // check for match
		{
			/*
             * Base mnemonic followed be O, ., L, A
             */

			strcat(mnem, itab[i].mnem);
			if (itab[i].flags & FL_OE)  if (op & M_OE) strcat(mnem, "o");
			if (itab[i].flags & FL_RC)  if (op & M_RC) strcat(mnem, ".");
			if (itab[i].flags & FL_LK)  if (op & M_LK) strcat(mnem, "l");
			if (itab[i].flags & FL_AA)  if (op & M_AA) strcat(mnem, "a");

			/*
             * Print operands
             */

			switch (itab[i].format)
			{
			case F_RT_RA_RB:
				sprintf(oprs, "r%d,r%d,r%d", G_RT(op), G_RA(op), G_RB(op));
				break;

			case F_RT_RA_0_SIMM:
				if (G_RA(op))
					sprintf(oprs, "r%d,r%d,%s", G_RT(op), G_RA(op), signed16);
				else
					sprintf(oprs, "r%d,0,%s", G_RT(op), signed16);
				break;

			case F_ADDIS:
				if (G_RA(op))
					sprintf(oprs, "r%d,r%d,0x%04X", G_RT(op), G_RA(op), G_SIMM(op));
				else
					sprintf(oprs, "r%d,0,0x%04X", G_RT(op), G_SIMM(op));
				break;

			case F_RT_RA_SIMM:
				sprintf(oprs, "r%d,r%d,%s", G_RT(op), G_RA(op), signed16);
				break;

			case F_RT_RA:
				sprintf(oprs, "r%d,r%d", G_RT(op), G_RA(op));
				break;

			case F_RA_RT_RB:
				sprintf(oprs, "r%d,r%d,r%d", G_RA(op), G_RT(op), G_RB(op));
				break;

			case F_RA_RT_UIMM:
				sprintf(oprs, "r%d,r%d,0x%04X", G_RA(op), G_RT(op), G_UIMM(op));
				break;

			case F_LI:
				disp = G_LI(op) * 4;
				if (disp & 0x02000000)	// sign extend
					disp |= 0xfc000000;
				sprintf(oprs, "0x%08X", disp + ((op & M_AA) ? 0 : pc));
				break;

			case F_BCx:
				disp = G_BD(op) * 4;
				if (disp & 0x00008000)
					disp |= 0xffff0000;

				if (G_BO(op) & 0x10)	// BI is ignored (don't print CR bit)
					sprintf(oprs, "0x%02X,%d,0x%08X", G_BO(op), G_BI(op), disp + ((op & M_AA) ? 0 : pc));
				else					// BI gives us the condition bit
					sprintf(oprs, "0x%02X,cr%d[%s],0x%08X", G_BO(op), G_BI(op) / 4, crbit[G_BI(op) & 3], disp + ((op & M_AA) ? 0 : pc));
				break;

			case F_BO_BI:
				if (G_BO(op) & 0x10)	// BI is ignored (don't print CR bit)
					sprintf(oprs, "0x%02X,%d", G_BO(op), G_BI(op));
				else
					sprintf(oprs, "0x%02X,cr%d[%s]", G_BO(op), G_BI(op) / 4, crbit[G_BI(op) & 3]);
				break;

			case F_CMP:
				if (G_L(op))
					strcat(mnem, "d");
				if (G_CRFD(op) == 0)
					sprintf(oprs, "r%d,r%d", G_RA(op), G_RB(op));
				else
					sprintf(oprs, "cr%d,r%d,r%d", G_CRFD(op), G_RA(op), G_RB(op));
				break;

			case F_CMP_SIMM:
				if (G_L(op))
					strcat(mnem, "d");
				if (G_CRFD(op) == 0)
					sprintf(oprs, "r%d,%s", G_RA(op), signed16);
				else
					sprintf(oprs, "cr%d,r%d,%s", G_CRFD(op), G_RA(op), signed16);
				break;

			case F_CMP_UIMM:
				if (G_L(op))
					strcat(mnem, "d");
				if (G_CRFD(op) == 0)
					sprintf(oprs, "r%d,0x%04X", G_RA(op), G_UIMM(op));
				else
					sprintf(oprs, "cr%d,r%d,0x%04X", G_CRFD(op), G_RA(op), G_UIMM(op));
				break;

			case F_RA_RT:
				sprintf(oprs, "r%d,r%d", G_RA(op), G_RT(op));
				break;

			case F_CRBD_CRBA_CRBB:
				sprintf(oprs, "cr%d[%s],cr%d[%s],cr%d[%s]", G_CRBD(op) / 4, crbit[G_CRBD(op) & 3], G_CRBA(op) / 4, crbit[G_CRBA(op) & 3], G_CRBB(op) / 4, crbit[G_CRBB(op) & 3]);
				break;

			case F_RA_0_RB:
				if (G_RA(op))
					sprintf(oprs, "r%d,r%d", G_RA(op), G_RB(op));
				else
					sprintf(oprs, "0,r%d", G_RB(op));
				break;

			case F_RT_RA_0_RB:
				if (G_RA(op))
					sprintf(oprs, "r%d,r%d,r%d", G_RT(op), G_RA(op), G_RB(op));
				else
					sprintf(oprs, "r%d,0,r%d", G_RT(op), G_RB(op));
				break;

			case F_FRT_FRB:
				sprintf(oprs, "f%d,f%d", G_RT(op), G_RB(op));
				break;

			case F_FRT_FRA_FRB:
				sprintf(oprs, "f%d,f%d,f%d", G_RT(op), G_RA(op), G_RB(op));
				break;

			case F_FCMP:
				sprintf(oprs, "cr%d,f%d,f%d", G_CRFD(op), G_RA(op), G_RB(op));
				break;

			case F_FRT_FRA_FRC_FRB:
				sprintf(oprs, "f%d,f%d,f%d,f%d", G_RT(op), G_RA(op), G_REGC(op), G_RB(op));
				break;

			case F_FRT_FRA_FRC:
				sprintf(oprs, "f%d,f%d,f%d", G_RT(op), G_RA(op), G_REGC(op));
				break;

			case F_RT_D_RA_0:
				if (G_RA(op))
					sprintf(oprs, "r%d,%s(r%d)", G_RT(op), signed16, G_RA(op));
				else
					sprintf(oprs, "r%d,0x%08X", G_RT(op), (UINT32) ((INT16) G_D(op)));
				break;

			case F_RT_D_RA:
				sprintf(oprs, "r%d,%s(r%d)", G_RT(op), signed16, G_RA(op));
				break;

			case F_FRT_D_RA_0:
				if (G_RA(op))
					sprintf(oprs, "f%d,%s(r%d)", G_RT(op), signed16, G_RA(op));
				else
					sprintf(oprs, "f%d,0x%08X", G_RT(op), (UINT32) ((INT16) G_D(op)));
				break;

			case F_FRT_D_RA:
				sprintf(oprs, "f%d,%s(r%d)", G_RT(op), signed16, G_RA(op));
				break;

			case F_FRT_RA_RB:
				sprintf(oprs, "f%d,r%d,r%d", G_RT(op), G_RA(op), G_RB(op));
				break;

			case F_FRT_RA_0_RB:
				if (G_RA(op))
					sprintf(oprs, "f%d,r%d,r%d", G_RT(op), G_RA(op), G_RB(op));
				else
					sprintf(oprs, "f%d,0,r%d", G_RT(op), G_RB(op));
				break;

			case F_RT_RA_0_NB:
				if (G_RA(op))
					sprintf(oprs, "r%d,r%d,%d", G_RT(op), G_RA(op), G_NB(op) ? G_NB(op) : 32);
				else
					sprintf(oprs, "r%d,0,%d", G_RT(op), G_NB(op) ? G_NB(op) : 32);
				break;

			case F_CRFD_CRFS:
				sprintf(oprs, "cr%d,cr%d", G_CRFD(op), G_CRFS(op));
				break;

			case F_MCRXR:
				sprintf(oprs, "cr%d", G_CRFD(op));
				break;

			case F_RT:
				sprintf(oprs, "r%d", G_RT(op));
				break;

			case F_MFFSx:
				sprintf(oprs, "f%d", G_RT(op));
				break;

			case F_FCRBD:
				sprintf(oprs, "fpscr[%d]", G_CRBD(op));
				break;

			case F_RT_SPR:
				sprintf(oprs, "r%d,", G_RT(op));
				SPR(oprs, G_SPR(op));
				break;

			case F_RT_DCR:
				sprintf(oprs, "r%d,", G_RT(op));
				DCR(oprs, G_DCR(op));
				break;

			case F_MFSR:
				sprintf(oprs, "r%d,sr%d", G_RT(op), G_SR(op));
				break;

			case F_MTCRF:
				sprintf(oprs, "0x%02X,r%d", G_CRM(op), G_RT(op));
				break;

			case F_MTFSFx:
				sprintf(oprs, "0x%02X,f%d", G_FM(op), G_RB(op));
				break;

			case F_MTFSFIx:
				sprintf(oprs, "cr%d,0x%X", G_CRFD(op), G_IMM(op));
				break;

			case F_MTSPR:
				SPR(oprs, G_SPR(op));
				sprintf(oprs, "%s,r%d", oprs, G_RT(op));
				break;

			case F_MTDCR:
				DCR(oprs, G_DCR(op));
				sprintf(oprs, "%s,r%d", oprs, G_RT(op));
				break;

			case F_MTSR:
				sprintf(oprs, "sr%d,r%d", G_SR(op), G_RT(op));
				break;

			case F_RT_RB:
				sprintf(oprs, "r%d,r%d", G_RT(op), G_RB(op));
				break;

			case F_RA_RT_SH_MB_ME:
				sprintf(oprs, "r%d,r%d,%d,%d,%d", G_RA(op), G_RT(op), G_SH(op), G_MB(op), G_ME(op));
				break;

			case F_RLWNMx:
				sprintf(oprs, "r%d,r%d,r%d,%d,%d", G_RA(op), G_RT(op), G_RB(op), G_MB(op), G_ME(op));
				break;

			case F_SRAWIx:
				sprintf(oprs, "r%d,r%d,%d", G_RA(op), G_RT(op), G_SH(op));
				break;

			case F_RB:
				sprintf(oprs, "r%d", G_RB(op));
				break;

			case F_TW:
				sprintf(oprs, "%d,r%d,r%d", G_TO(op), G_RA(op), G_RB(op));
				break;

			case F_TWI:
				sprintf(oprs, "%d,r%d,%s", G_TO(op), G_RA(op), signed16);
				break;

			case F_NONE:
			default:
				break;
			}

			if ((itab[i].flags & FL_LK) && (op & M_LK))
				flags |= DASMFLAG_STEP_OVER;
			else if (itab[i].flags & FL_SO)
				flags |= DASMFLAG_STEP_OUT;

			buffer += sprintf(buffer, "%s", mnem);
			for( j = strlen(mnem); j < 10; j++ ) {
				buffer += sprintf(buffer, " ");
			}
			buffer += sprintf(buffer, "%s", oprs);
			return 4 | flags;
        }
    }

	sprintf(buffer, "?");
    return 4 | flags;
}

CPU_DISASSEMBLE( powerpc )
{
	UINT32 op = *(UINT32 *)oprom;
	op = BIG_ENDIANIZE_INT32(op);
	return ppc_dasm_one(buffer, pc, op);
}
